KR20170010571A - Electronic Proportional Pressure Reducing Valve - Google Patents

Abstract

An electronic proportional pressure reduction valve is disclosed. The electronic proportional pressure reduction valve comprises: a solenoid unit having an armature moved by a magnetic force; and a valve unit coupled to the solenoid unit, having a valve sleeve having a plurality of ports, and having a valve piston disposed inside the valve sleeve to divide an inner space of the valve sleeve into a plurality of chambers. The valve piston has a bore and a plurality of through-holes to connect the plurality of chambers.

Description

Electronic Proportional Pressure Reducing Valve

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic proportional pressure reducing valve, and more particularly, to an electronic proportional pressure reducing valve for controlling the flow and pressure of a fluid.

In general, a large number of hydraulic control valves are used in the hydraulic equipment. The hydraulic control valve controls the flow of the fluid from the hydraulic pump so that the desired operation is achieved in each actuator. The control method of the hydraulic control valve includes a pilot method in which the piston of the control valve is operated with pilot pressure transmitted from the outside, a manual operation mode in which the piston connected to the lever is manually operated by operating the lever manually, And an electronic operation system for operating a piston with a solenoid.

The electronic proportional pressure reducing valve is an electronically operated valve, and is largely composed of a solenoid portion for generating an electromagnetic force and a valve portion used as a fluid passage.

The solenoid portion includes a housing, a coil for generating magnetic force, and an armature for moving in accordance with the magnetic force of the coil.

The valve includes a piston moving by the movement of the armature, and a sleeve having various ports. The valve selectively opens and closes various ports through movement of the piston to control the pressure and flow of the fluid.

Such a conventional proportional pressure reducing valve is formed in a complicated shape, which complicates the manufacturing process and increases manufacturing time and cost.

Korean Patent Publication No. 10-2011-0124254

SUMMARY OF THE INVENTION It is an object of the present invention to provide an electron proportional pressure reducing valve which is formed in a simple shape in order to simplify the manufacturing process and reduce manufacturing time and cost.

According to an aspect of the present invention, there is provided an electronic proportional pressure reducing valve comprising: a solenoid unit including an armature moving by a magnetic force; And a valve sleeve coupled to the solenoid portion and having a plurality of ports formed thereon and a plurality of lands disposed within the valve sleeve to abut the armature with a plurality of lands so that the inner space of the valve sleeve is divided into a plurality of chambers And a valve portion having a valve piston to partition the valve piston, wherein the valve piston is formed with a bore and a plurality of through holes, so that the plurality of chambers can communicate with each other.

Wherein the plurality of ports includes a first port formed on the outer periphery of the valve sleeve in proximity to the solenoid portion, a second port formed on an outer periphery of the valve sleeve at a predetermined distance in the axial direction from the first port, And a third port formed at an axial end of the sleeve.

Wherein the plurality of lands include: a first land formed on an outer circumference of the valve piston and closely formed on one inner circumferential surface of the valve sleeve adjacent to the solenoid portion; a third land formed on an outer circumference of the valve piston, And a second land formed between the first land and the third land on the outer circumference of the valve piston.

The plurality of through holes may include a first through hole formed through the second land in an axial direction and a second through hole formed through the second land in a circumferential direction.

The central portion of the second land may be smaller in diameter than the outer frame portion.

And the third land may be wider than the second port.

The third land may be smaller in diameter than the first land or the second land.

Wherein the plurality of chambers includes a first chamber in which a predetermined portion of a valve piston abutting the armature is located, a second chamber that is an inner space of the valve sleeve between the first land and the second land, And a third chamber that is the interior space of the valve sleeve between the third lands.

The bore may be formed inwardly from the axial end of the valve piston to allow communication between the first chamber and the third port.

The inner diameter of the valve sleeve forming the third port may be smaller than the inner diameter of the valve sleeve forming the second chamber and the third chamber.

The plurality of through holes may include a third through hole formed in an outer periphery of the valve piston located in the first chamber so that the plurality of chambers communicate with each other through the bore.

The valve piston being moved by movement of the solenoid portion includes a plurality of positions, wherein the plurality of positions include a first position for communicating the first port and the third port, a first position for communicating the first port, A second position for disconnecting the third port, and a third position for communicating the first port and the second port.

The valve unit may further include a load spring for returning the valve piston from the second position or the third position to the first position when there is no movement of the armature.

The solenoid unit may further include a magnetic coil surrounding the armature, and the armature may be moved by a magnetic force generated by the magnetic coil.

The first port may be an output port.

A notch may be formed in the second land and the third land.

Therefore, according to the electronic proportional pressure reducing valve according to the embodiment of the present invention, fluid flow and pressure control are possible through a simple shape piston.

Further, the shape of the piston is simplified, the manufacturing process is simple, and manufacturing time and cost can be reduced.

1 is a perspective view of an electronic proportional pressure reducing valve according to an embodiment of the present invention.
2 is a cross-sectional view of an electronic proportional pressure reducing valve according to an embodiment of the present invention.
3 is a side view of a valve piston showing a notch formed in a valve piston of an electronic proportional pressure reducing valve according to an embodiment of the present invention.
FIGS. 4 to 8 are explanatory views illustrating the operation of the electronic proportional pressure reducing valve according to the embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly explain the present invention, parts not related to the description are omitted, and the same reference numerals in the drawings indicate the same members.

Throughout the specification, when an element is referred to as " including " an element, it does not exclude other elements unless specifically stated to the contrary.

1 and 2, an electron proportional pressure reducing valve according to an embodiment of the present invention may include a solenoid unit 100 and a valve unit 200, and may include a solenoid unit 100 operated by a control signal (E.g., a pump), an output unit (e.g., an actuator), and a storage unit (e.g., a tank) that can be connected to various ports through the communication port of the various ports formed in the valve unit 200, Which is a kind of solenoid valve that controls the flow and pressure of the fluid that is input or output in the flow path.

The solenoid portion 100 may include an armature 110, an armature housing 120, a magnetic coil 130, a body cover 140, an adjustment screw 150, a rod spring 160, a flange 170, have.

The armature 110 may be formed in a cylindrical shape. The armature 110 may have a guide groove 111 formed on one side (left side in FIG. 2) and a rod-shaped armature rod 113 on the other side (right side in FIG. 2). The armature 110 can be moved in either one direction (right direction in FIG. 1) by the peripheral magnetic force.

The armature housing 120 can receive the armature 110 therein. The armature housing 120 may be formed such that the inner circumferential surface thereof is in close contact with the outer circumferential surface of the armature 110. The armature housing 120 may have holes formed on both sides thereof to communicate with the outside air.

The magnetic coil 130 is formed of a conductor through which electric current can flow and may be provided to surround the outer circumference of the armature housing 120. The magnetic coil 130 may be divided into a coil head 131 and a coil body 133 and a washer Wa may be provided between the coil head 131 and the coil body 133. When a current flows in the magnetic coil 130, a magnetic force is generated, and the armature 110 positioned in the magnetic coil 130 is moved in one direction (reference right direction in FIG. 2) by the generated magnetic force It moves.

The body cover 140 may be formed in a cylindrical shape so as to cover the entire magnetic coil 130. The body cover 140 may include an outer cover 141 and a one-sided cover 143. The outer cover 141 and the end cover 143 are preferably separable from each other to facilitate assembly, but may be integrally formed.

The end face of the end face cover 143 may be in contact with a bearing (Br) provided at one side of the armature housing 120. [ An external circlip (EC) for fixing the bearing (Br) may be further provided on one side of the armature housing (120).

The adjustment screw 150 may be coupled to a nut secured to one side of the armature housing 120 and a predetermined portion thereof may be located inside the armature housing 120. When the adjusting screw 150 is further inserted into the armature housing 120 by manual operation, the position of the armature 110 can be adjusted.

The rod spring 160 is disposed in the guide groove 111 of the armature 110 so that one end of the rod spring 160 is in contact with the adjusting screw 150 and the other end thereof is in contact with the armature 110. The rod spring 160 is compressed when the adjusting screw 150 is further inserted into the armature housing 120 and is then compressed in a state in which the armature 110 is no longer compressed Can be moved.

The flange 170 can be formed in a protruding shape for one side (left side in FIG. 2) to be inserted into the other side (right side in FIG. 2) of the armature housing 120 and the main body portion can be inserted into the armature housing 120, And the body cover 140, respectively. A ring 1 for sealing may be provided between the inner circumference of the armature housing 120 and the outer circumference of the protruding portion of the flange 170 inserted into the armature housing 120. The flange 170 may have a hole formed at its center. Here, the armature rod 113 of the armature 110 can be positioned through the flange 170 through a hole formed in the center of the flange 170.

The flange 170 may be formed in such a manner that the other side thereof can receive a part of the valve unit 200. The other side of the flange 170 may be formed to have a tight grip on the outer circumference of the valve unit 200. A ring 2 for sealing may be provided between the inner circumference on the other side of the flange 170 and the outer circumference of the valve unit 200 .

The valve unit 200 serves as a flow path and may include a valve sleeve 210, a valve piston 220, a rod spring 230, and the like.

The valve sleeve 210 may have an internal hollow cylindrical shape. The valve sleeve 210 can be inserted into the flange 170 at a predetermined position. A plurality of first ports A and second ports P may be formed on the outer circumference of the valve sleeve 210 and a third port T may be formed on the axial end of the valve sleeve 210. The first port A is formed close to the solenoid portion 100 on the outer circumference of the valve sleeve 210 and the second port P is formed on the outer circumference of the valve sleeve 210 from the first port A in the axial direction As shown in FIG.

Here, the first port A may be connected to an output unit (actuator) that receives fluid and operates through the fluid, the second port P may be connected to an input unit (pump) that supplies fluid, The port T may be connected to a reservoir (tank) for storing the fluid. That is, the first port A is used as an output port, the second port P is used as an input port, and the third port T is used as a tank port.

The outer circumferential portion of the valve sleeve 210 may protrude to facilitate connection with the output unit, the input unit, and the like.

The valve piston 220 may be formed in a columnar shape. The valve piston 220 may be disposed within the valve sleeve 210. The valve piston 220 may be disposed such that one side (left side in FIG. 1) of the valve piston 220 is in contact with the armature rod 113 of the armature 110.

The valve pistons 220 may include a plurality of lands protruding in the circumferential direction in the circumferential direction and the plurality of lands include a first land 221, a second land 222, and a third land 223 can do. The first land 221 is located closely to the inner circumferential surface of one side of the valve sleeve 210 adjacent to the solenoid 210. The third land 223 is located farthest from the solenoid 210 and the second land 222 May be positioned between the first land 221 and the third land 223.

The second land 222 is positioned such that a predetermined portion thereof is opposed to the first port A of the valve sleeve 210 and the third land 223 is opposed to the second port P of the valve sleeve 210, . The width of the third land 223 is preferably larger than the second port P. [ In addition, the third land 223 is preferably smaller in diameter than the first land 221 or the second land 222.

A plurality of through holes may be formed in the second land 222 of the valve piston 220. The plurality of through holes include a first through hole 222a and a second through hole 222b. The first through hole 222a may be formed through the second land in the axial direction (axial direction of the valve piston of FIG. 2). The second through hole 222b may be formed through the second land 222 in the circumferential direction (circumferential direction of the valve piston of FIG. 2). It is preferable that the first through hole 222a and the second through hole 222b are not communicated with each other at a specific position of the valve piston 220 to be described later.

The second land 222 may have a diameter smaller than that of the outer portion. That is, the central portion of the second land 222 does not touch the inner circumferential surface of the valve sleeve 210 between the first port A and the second port P, and the outer portion of the second land 222 is connected to the first port A and the second port (P) of the valve sleeve (210). For example, when the outer periphery of the second land 222 (refer to FIG. 2) abuts on the inner circumferential surface of the valve sleeve 210 between the first port A and the second port P, A variable chamber is formed between the central portion and the inner circumferential surface of the valve sleeve 210 between the first port (A) and the second port (P).

When the outer side of the second land 222 on the left side of the second land 222 does not abut against the inner circumferential surface of the valve sleeve 210 between the first port A and the second port P, A). Further, the variable chamber communicates with the second through hole 222b.

In addition, the valve piston 220 may be formed with a bore 224. The bore 224 may be formed by being deeply dug inwardly from the shaft end (reference right end in Fig. 1) of the valve piston 220. The bore 224 is preferably formed at the center of the valve piston 220, but is not limited thereto.

When the valve piston 220 is disposed inside the valve sleeve 210, the inner space of the valve sleeve 210 is separated from the first chamber 211, the second chamber 212, and the second chamber 211 by a plurality of lands of the valve piston 220. And the third chamber 213.

The first chamber 211 may include an inner space of the flange 170 and an inner space of one side of the valve sleeve 210 (left side in FIG. 1). That is, the first chamber 211 may be a space in which a predetermined portion of the valve piston 220, which abuts the armature 113, is located.

The second chamber 212 may be the interior space of the valve sleeve between the first land 221 and the second land 222. And the second chamber 212 can communicate with the first port A. [ Here, the variable chamber described above may be connected to or disconnected from the second chamber 212 depending on the position of the valve piston 200.

The third chamber 213 may be the inner space of the valve sleeve between the second land 222 and the third land 223. The third chamber 213 may be disconnected or disconnected from the second port P depending on the position of the valve piston 200.

It is also preferable that the inner diameter of the valve sleeve 210 forming the third port T is smaller than the inner diameter of the valve sleeve forming the second chamber 212 and the third chamber 213. In addition, the sizes of the first chamber 211, the second chamber 212, the third chamber 213, and the third port T can be varied by the movement of the valve piston 220.

The valve piston 210 located in the first chamber 211 for communication between the first chamber 211, the second chamber 212, the third chamber 213 and the third port T of the valve sleeve 210 220 may have a third through hole 224a formed on the outer periphery thereof. The third through hole 224a can communicate the first chamber 211 and the third port T through the bore 224. [

Accordingly, the first chamber 211 and the second chamber 212 can communicate with each other through the second through hole 222b, the bore 224, and the third through hole 224a. The second chamber 212 and the third chamber 213 may communicate with each other through the first through hole 222a. The second chamber 212 and the third port T may communicate with each other through the second through hole 222b and the bore 224. [ The first through hole 222a, the second through hole 222b, and the third through hole 224a may be semicircular or circular, but are not limited thereto.

The rod spring 230 is a member having an elastic restoring force and may be located in the first chamber 211. The other end of the rod spring 23 can abut against the inner wall of the valve sleeve 210 while the other end of the rod spring 23 abuts against one side of the valve piston 220 abutting against the armature rod 113 of the armature 110.

The rod spring 230 is compressed when the valve piston 220 moves to the right side (reference in FIG. 2) by the armature 210 and is expanded through the restoring force when the armature 210 force disappears, It can be returned to the position before it is moved by the moving mechanism 210.

Accordingly, the electromagnetic proportional pressure reducing valve according to the embodiment of the present invention is configured to move the valve piston 220 by using the movement of the armature 110 by the control signal so that the first port A and the third port T The first port A and the second port P are communicated and the third port T is disconnected in the initial state in which the second port P is disconnected. The proportional pressure reducing valve may also be configured to control the flow and pressure of the fluid that is input or output to and from an output (e.g., an actuator), an input (e.g., a pump), and a reservoir (e.g., a tank) Can be controlled.

Referring to FIG. 3, it can be seen that a notch is formed in the valve piston of the electron proportional pressure reducing valve according to the embodiment of the present invention.

A notch n may be formed in the second land 222 and the third land 223 of the valve piston 220. The notch n may be formed by cutting a predetermined portion of the second land 222 Or a predetermined portion of the outer circumference of the third land may be formed by grinding. The notch n may be formed to prevent the pressure of the fluid flowing into or out of the first port A and the second port P from changing abruptly.

Hereinafter, the operation of the electronic proportional pressure reducing valve according to the embodiment of the present invention will be described with reference to FIGS. 4 to 8. FIG.

In FIG. 4, the electronic proportional pressure reducing valve is in an initial state in which there is no control signal and the valve piston 220 does not move. At this time, the second land 222 of the valve piston 220 is not in contact with the inner peripheral surface of the valve sleeve 210, and the first chamber 211, the second chamber 212, . That is, the electronic proportional pressure reducing valve in the initial state is in a state in which the first port A and the third port T are communicated and the second port P is blocked by the third land. Accordingly, an output unit (actuator) connected to the first port A and a storage unit (tank) connected to the third port T can communicate with each other. The position of the valve piston 220 which communicates the first port A and the third port T when the electron proportional pressure reducing valve is in an initial state is defined as a first position.

5, when an approximately small amount of current I flows in the magnetic coil 130 according to a control signal, a magnetic force is generated around the magnetic coil 130 by the current I, The armature 110 is moved to the right side (reference in FIG. 5) by the armature 110 and the valve piston 220 is moved to the right side (reference in FIG. 5) by a predetermined distance.

The outer edge of the left side of the second land 222 of the valve piston 220 is moved to a position where it abuts against the inner circumferential surface of the valve sleeve 210. At this time, 212 and the third chamber 213 are disconnected from the first chamber 211 by the second land 222 of the valve piston 220. Here, the second chamber 212 and the third chamber 213 are in communication with each other through the first through hole 222a.

Further, the third land 223 of the valve piston 220 is moved to the right (reference to FIG. 5), but is still blocking the second port P. [ 5 is a state in which the first port A, the second port P, and the third port T are disconnected by the valve piston 220. In other words, The position of the valve piston 220 which disconnects the first port A, the second valve P and the third port T is defined as a second position.

6, when a larger amount of current I flows in the magnetic coil 130 according to the control signal, a high magnetic force is generated around the magnetic coil 130 by the current I, and a high magnetic force The armature 110 is further moved to the right (reference in FIG. 6) by the armature 110 and the valve piston 220 is moved to the right (reference in FIG. 6) by the armature 110 more.

The left outer edge of the second land 222 of the valve piston 220 is surely abutted against the inner circumferential surface of the valve sleeve 210 forming the above-described variable chamber. The third land 223 of the valve piston 220 is further moved to the right (reference to FIG. 6) to communicate the second port P with the third chamber 213. At this time, the first port (A) and the second port (P) communicate with each other. The position of the valve piston 220 that communicates the first port A and the second port P is defined as a third position.

For example, at the third position of the valve piston 220, when the input unit (pump) pressurizes the fluid to transfer the fluid to the second port P, the fluid flows into the third chamber 213 Through the first through hole 222a and the second chamber 212 to the first port A and finally to the output port (actuator) connected to the first port A . Thus, the output section (actuator) can be driven through the supplied fluid.

7, when a small amount of current I flows again into the magnetic coil 130 in accordance with the control signal, the valve piston 220 is moved to the valve position shown in FIG. 5 by the restoring force of the rod spring 230, The first port A, the second port P and the third port T are disconnected by the valve piston 220 in the same manner as in Fig. At this time, unlike the electron proportional pressure reducing valve of FIG. 5, the electron proportional pressure reducing valve is a state in which the fluid flowing from the second port P into the second chamber 212 and the third chamber 213 remains.

8, when the current I does not flow through the magnetic coil 130 due to the absence of a control signal, the valve piston 220 is moved to the valve piston 220 of FIG. 4 by the restoring force of the rod spring 230, The first port A and the third port T are communicated with each other and the second port P is blocked by the third land 223 in the same manner as in Fig.

For example, when the fluid supplied from the output part (actuator) is discharged at the first position of the valve piston 220, the fluid flows into the first port A, and the fluid communicates with the first port A (Tank) connected to the third port T and finally flows into the third port T through the second chamber 212, the second through hole 222b, and the bore 224 in order, . Therefore, the electronic proportional pressure reducing valve according to the embodiment of the present invention can be used as a flow path for returning the fluid supplied to the output part (actuator) to the storage part (tank part).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: Solenoid part
110: Armature
120: Armature housing
130: magnetic coil
140: Body cover
150: Adjusting screw
160: Load spring
170: flange
200:
210: Valve sleeve
A: First port
P: second port
T: Third port
211: first chamber
212: second chamber
213: Third chamber
220: valve piston
221: 1st land
222: second land
223: Third Land
224:
230: Load spring

Claims (16)

A solenoid portion having an armature moving by a magnetic force; And
A valve sleeve coupled to the solenoid portion and having a plurality of ports formed thereon and a plurality of lands disposed in the valve sleeve to abut the armature with a plurality of lands to divide the inner space of the valve sleeve into a plurality of chambers, And a valve portion having a valve piston,
Wherein the valve piston is formed with a bore and a plurality of through holes to communicate the plurality of chambers. The method according to claim 1,
Wherein the plurality of ports include:
A first port formed on an outer circumference of the valve sleeve in proximity to the solenoid portion, a second port formed on an outer circumference of the valve sleeve at a predetermined distance in the axial direction from the first port, and a second port formed at an axial end portion of the valve sleeve The third port being connected to the second port. 3. The method of claim 2,
Wherein the plurality of lands
A first land formed on an outer circumference of the valve piston and closely formed on an inner circumferential surface of one side of the valve sleeve adjacent to the solenoid portion, a third land formed on an outer circumference of the valve piston so as to face the second port, And a second land formed between the first land and the third land on the outer periphery. The method of claim 3,
Wherein the plurality of through-
A first through hole formed in the second land in an axial direction and a second through hole formed in the second land in a circumferential direction,
And an electromagnetic proportional pressure reducing valve. The method of claim 3,
And the central portion of the second land is smaller in diameter than the outer frame portion. The method of claim 3,
And the third land is wider than the second port. The method of claim 3,
And the third land is smaller in diameter than the first land or the second land. The method of claim 3,
Wherein the plurality of chambers comprises:
A second chamber which is an inner space of the valve sleeve between the first land and the second land, a second chamber which is a space inside the valve sleeve between the first land and the second land, And a third chamber which is an inner space of the valve sleeve. 9. The method of claim 8,
Wherein the bore is formed inwardly from an axial end of the valve piston so as to communicate the first chamber and the third port. 9. The method of claim 8,
Wherein an inner diameter of the valve sleeve forming the third port is smaller than an inner diameter of the valve sleeve forming the second chamber and the third chamber. 9. The method of claim 8,
Wherein the plurality of through-
And a third through hole formed in an outer periphery of the valve piston located in the first chamber so that the plurality of chambers communicate with each other through the bore. The method of claim 3,
Wherein the valve piston moved by the movement of the solenoid portion includes a plurality of positions,
Wherein the plurality of positions include a first position for communicating the first port and the third port, a second position for disconnecting the first port, the second port, and the third port, And a third position for communicating the port with the third proportional pressure reducing valve. 13. The method of claim 12,
The valve unit includes:
And a load spring for returning the valve piston from the second position or the third position to the first position when there is no movement of the armature. The method according to claim 1,
The solenoid unit includes:
And a magnetic coil surrounding the armature,
And the armature is moved by a magnetic force generated by the magnetic coil. 3. The method of claim 2,
And the first port is an output port. The method of claim 3,
And a notch is formed in the second land and the third land.

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